Magnetic belt assembly

ABSTRACT

A magnetic belt assembly is provided. The assembly includes a first belt portion having a first coupling member and a second belt portion having a second coupling member. Each of the first coupling member and the second coupling member includes a plurality of magnets that is structurally flexible such that each magnet of the plurality of magnets is angularly positionable relative to each other magnet of the plurality of magnets to form a non-planar surface.

RELATED APPLICATION DATA

This application is a continuation-in-part of U.S. patent applicationSer. No. 14/330,362 filed Jul. 14, 2014, which claims benefit to U.S.Provisional Application No. 61/957,912 filed Jul. 13, 2013, each ofwhich is hereby incorporated in their entirety herein by reference.

FIELD OF THE DISCLOSURE

The present disclosure relates to magnetic assemblies and, inparticular, to magnetic belt assemblies.

BACKGROUND OF THE DISCLOSURE

Craftsmen in industries such as the vehicle wrap, automotive paintprotection, automotive bed liner, home decor, automotive sign andgraphics, woodworking, and construction industries, as well as anyindustry professional that uses small tools during the performance ofhis or her job, require easy and efficient access to the tools of theirtrade. Particularly in the adhesive wrap industry, a graphics installerapplies adhesive sheet materials or tape to the exterior of a vehicle,watercraft, aircraft, or any other surface to be covered. A variety oftools and supplies are utilized to apply the adhesive sheet materials ortape including squeegees of varying size, type, or function, levels,tape measures, screw drivers, wrenches, nails, pencils, knives, razors,scissors, and tape reels. The graphics installer must move to variousstations or locations of the vehicle or surface, including locationsthat are very low to the ground or that have very little space forinstaller movement. Conventional tool belts or other holders are toobulky to be utilized in the tight spaces in which graphics installersmust operate. Further, conventional belts and holders are not easilyremoved in such tight spaces and installers cannot reposition or easilyreattach the conventional belts or holders as installation moves todifferent areas of the work surface.

Therefore, there remains a need for a belt assembly that is quickly andeasily removed. Additionally, there remains a need for a belt assemblythat allows one or more objects to be quickly and easily attachedthereto. Further, there remains a need for a belt assembly that iscapable of being reattached at another location, such as a vehiclesurface, to allow installers to access necessary tools for completion ofthe adhesive wrap work.

SUMMARY OF THE DISCLOSURE

In accordance with an aspect of the disclosure, a magnetic belt assemblyis provided. The belt assembly includes a first belt portion having afirst coupling member, and a second belt portion having a secondcoupling member, wherein each of the first coupling member and thesecond coupling member comprises a plurality of magnets that isstructurally flexible such that each magnet of the plurality of magnetsis angularly positionable relative to each other magnet of the pluralityof magnets to form a non-planar surface.

The first belt portion may define a first end of the magnetic beltassembly. The second belt portion may define a second end of themagnetic belt assembly. The second belt portion may define a connectingportion of the magnetic belt assembly between the first end and a secondend of the magnetic belt assembly. The first belt portion may include afirst layer and a second layer, the first layer being coupled to thesecond layer to embed the first coupling member therebetween. The secondbelt portion may include the first layer and the second layer, the firstlayer being coupled to the second layer to embed the second couplingmember therebetween. The first layer may be coupled to the second layerbetween two adjacent magnets. The belt assembly may further include aninternal cavity between the first layer and the second layer, theinternal cavity extending continuously from the first end of themagnetic belt assembly to the second end of the magnetic belt assembly.The first layer and the second layer may be sewn together continuouslyfrom the first end to the second end to form the internal cavity. Theplurality of magnets may extend from a first end of the magnetic beltassembly to a second end of the magnetic belt assembly. The non-planarsurface may be formed by each magnet of the plurality of magnets beingsplit from each other magnet of the plurality of magnets. Each magnet ofthe plurality of magnets may be arranged in a varied polarity array suchthat two magnets that are angularly positionable to form a non-planarsurface are positioned in the array with reversed polarity relative tothe other. Each of the plurality of magnets may be inflexible.

In accordance with an aspect of the present disclosure, a magnetic beltassembly is provided. The belt assembly includes a first belt portiondefining a first end of the magnetic belt assembly and having a firstcoupling member, a second belt portion defining a second end of themagnetic belt assembly and having a second coupling member, and a thirdbelt portion connecting the first end of the magnetic belt assembly tothe second end of the magnetic belt assembly and having a third couplingmember. Each of the first coupling member, the second coupling member,and the third coupling member comprises a plurality of magnets that isstructurally flexible such that each magnet of the plurality of magnetsis angularly positionable relative to and split from each other magnetof the plurality of magnets to form a non-planar surface.

The assembly may further include an internal cavity extending from thefirst end of the magnetic belt assembly to the second end of themagnetic belt assembly. The plurality of magnets may be disposed withinthe internal cavity and extend from the first end of the magnetic beltassembly to the second end of the magnetic belt assembly. The internalcavity may be formed by a first layer defining a first planar side ofthe magnetic belt assembly and being coupled to a second layer defininga second planar side of the magnetic belt assembly. A first layer and asecond layer may be sewn together continuously from the first end to thesecond end to form the internal cavity. Each magnet of the plurality ofmagnets may be arranged in a varied polarity array such that two magnetsthat are angularly positionable to form the non-planar surface arepositioned in the array with reversed polarity relative to the other.Each magnet of the plurality of magnets may be inflexible.

BRIEF DESCRIPTION OF THE FIGURES

While the specification concludes with claims particularly pointing outand distinctly claiming the present disclosure, the present disclosurewill be better understood from the following description in conjunctionwith the accompanying Drawing Figures, in which like reference numeralsidentify like elements, and wherein:

FIG. 1 is a front perspective view of a holding member or removablemember of an attachment assembly in accordance with aspects of thepresent disclosure;

FIG. 2 is a rear perspective view of a holding member or removablemember of an attachment assembly in accordance with further aspects ofthe present disclosure;

FIG. 3 is a front perspective view of an attachment member of anattachment assembly in accordance with further aspects of the presentdisclosure;

FIG. 4 is a front perspective view of a holding member or removablemember of an attachment assembly in accordance with aspects of thepresent disclosure;

FIG. 5 is an enlarged partial cross-sectional top view of an attachmentassembly in accordance with further aspects of the present disclosure;

FIG. 6 is a perspective view of a magnetic belt assembly in accordancewith aspects of the present disclosure;

FIG. 7 is a perspective view of a magnetic belt assembly in accordancewith aspects of the present disclosure;

FIG. 8 is a cross sectional view of a magnetic belt assembly inaccordance with aspects of the present disclosure; and

FIG. 9 is a cross sectional view of a magnetic belt assembly inaccordance with aspects of the present disclosure.

DETAILED DESCRIPTION

In the following detailed description of the preferred embodiment,reference is made to the accompanying drawings that form a part hereof,and in which is shown by way of illustration, and not by way oflimitation, a specific preferred embodiment in which the disclosure maybe practiced. It is to be understood that other embodiments may beutilized and that changes may be made without departing from the spiritand scope of the present disclosure.

Reference is now made to FIG. 1, which shows an attachment assembly 12in accordance with a preferred embodiment of the present disclosure. Theattachment assembly 12 shown in FIG. 1 includes a holding member 14,also referred to herein as a removable member 14, and an attachmentmember 16. The holding member 14 includes a main portion 18 having abody 22 that is substantially planar as shown in FIG. 1 and furthershown in FIG. 2, extending downward from an upper portion 20 of theholding member 14. In the preferred embodiment shown in FIG. 1, the coreof the upper portion 20, the main portion 18, and the body 22 iscomprised of saddle leather to permit flexibility while remainingdurable. At an outer portion 26 of the body 22 or main portion 18, oneor more pockets 44, also referred to herein as pouches, or loops 46 arepositioned as holding spaces 24 for a variety of tools, supplies, orother objects. The embodiment of FIG. 1 shows one large central pocket44 formed from a polypropylene material by stitching, attaching, orother coupling at two ends to the body 22 with a closed lower end toretain, hold, or store objects, such as tools or supplies. Several loops46 are formed on both sides of the pocket 44 by one or more strips ofelastic material that is stitched, attached, or otherwise coupled to thebody 22 at several coupling locations, as shown in FIG. 1. The elasticmaterial allows the loops 46, which have an open upper end and openlower end, to securely retain or hold a variety of smaller tools orobjects. The preferred embodiment of the present disclosure furtherincludes multiple loops 46 at the upper portion 20 with a pocket 44formed at the top edge of the holding member 14.

Referring now to FIG. 4, the holding member 14 is shown storing,retaining, or holding a variety of objects. The pocket 44 at the mainportion 18 is large enough to accommodate uniquely shaped or sizedobjects 86, such as scissors, a ruler or other tools. Loops 46 formed oneither side of the pocket 44 at the main portion are elastic toreleasably secure objects 82 such as pencils, knives, tweezers, or othersimilar tools. At the upper portion 20, the pocket 44 can hold, store,retain, or otherwise support objects such as a squeegee 80.Additionally, a series of loops 46 at the upper portion 20 supportssmaller squeegees 80 or other objects or tools 84 of similar size orshape, as shown in FIG. 4.

Referring now to FIG. 2, the back side of the holding member 14 of theattachment assembly 12 is shown. At the upper portion 20, a firstcoupling member 30 includes one or more magnets, which in the preferredembodiment includes a row or array of three magnets that are enclosedwithin a saddle leather core, shown in further detail in FIG. 5. Thefirst coupling member 30 attaches, couples, mates, is attracted to, oris otherwise designed to join a second coupling member 32 of theattachment member 16, as shown in FIG. 1.

Referring now to FIG. 3, one embodiment of the attachment member 16 isshown as a sleeve 68 having a first side portion 40 at an outer side anda second side portion 42, or first side 34 facing outward and a secondside 36 facing an inner direction, such as toward a person wearing theattachment member 16. The sleeve 68 of the embodiment shown in FIG. 3 ispositioned around a person's belt such that the second coupling member32 is positioned in an outward-facing direction.

An alternative embodiment of the attachment member 16, referenced inFIG. 5, includes the second coupling member 32 being incorporated into abelt 38. Further alternative embodiments may include second couplingmember 32 being incorporated into another article of clothing oraccessory located on a person's body, such as a shirt sleeve or a pantleg or pocket. These alternative embodiments allow direct attachment ofthe holding member 14 to a person rather than needing a separate articlefor attachment.

A craftsman uses the attachment assembly 12 of the preferred embodimentshown in FIGS. 1 and 3 by securing the attachment member 16 to his orher body, typically by threading his or her belt through the attachmentmember 16 and wearing the belt such that the attachment member 16 facesforward with the second coupling member 32 facing outward. The holdingmember 14, as shown in FIG. 1, may be initially attached to thecraftsman as he or she begins work, offering ease of access to tools,supplies, and other items as needed because of the convenient location.As the work surface or nature of the work requires the craftsman to movefrequently to different and often more restrictive areas, the holdingmember 14 may be quickly detached from the attachment member 16 andreattached to a work piece or surface, such as a metallic vehicle panel,a work bench, or other surface comprised of a ferrous or other materialto which the magnet(s) of the first coupling member 30 are capable ofattracted. After reattachment, the holding member 14 may be againdetached and reattached to a new surface as needed to provide adifferent, user-preferred method or location of access to the objects ofthe holding member 14 as the craftsman performs his or her work.

Referring now to FIG. 5, a top view of an embodiment of the attachmentassembly 12 is shown. The first coupling member 30 of the holding orremovable member 14 of the embodiment shown in FIG. 5 includes threemagnets 48 configured in a first array 50. An inner side 62 of theremovable member 14 faces the attachment member 16. The attachmentmember 16 of the embodiment shown in FIG. 5 is a belt 38 or otherclothing article or accessory housing the second coupling member 32having three magnets 48 configured in a second array 52. An inner sideof the attachment member 16 faces the person wearing the belt 48 whilean outer side 64 faces the removable member 14 such that the polarity ofthe first array 50 of magnets and the second array 52 of magnets permitsattraction between the attachment member 16 and the removable member 14.

As shown in the embodiment of FIG. 5, a first magnet in a first polarityconfiguration 54 is positioned in the first array 50 adjacent a secondmagnet in a second polarity configuration 56 different from said firstpolarity configuration 54. In the second array 52, a third magnet in thesecond polarity configuration 58 is positioned adjacent to a fourthmagnet in the first polarity configuration 60 such that the first andsecond magnets 54, 56 are properly attracted to the third and fourthmagnets 58, 60.

The particular configuration of each magnet 48 may be varied so long aseach of the magnets 48 positioned in the first array 50 is attracted toeach correspondingly positioned magnet 48 of the second array 52. As canbe expected, there are many possible configurations of mated arrays asdetermined by the number of magnets 48 in each array. Accordingly, thenumber of configurations is 2n where n is the number of magnets in eacharray. In the embodiment shown in FIG. 5, there are eightconfigurations. However, any number of magnets may be used to increaseor decrease the number of potential configurations, and any array shapeor design may be used to create the mated first array 50 and secondarray 52. The variety of polarity configurations allows forcustomization or organization opportunity as a particular removablemember 14 may only properly couple with a correct attachment member 16due to the unique, matching configuration of the magnets of each.Further, the first coupling member 30 or the second coupling member 32may not contain magnets, or ferromagnetic materials. If there are one ormore magnets 48, in an array or otherwise, incorporated as the firstcoupling member 30, the second coupling member 32 need only comprise aferrous or other material to which the magnet(s) are capable ofattracted, and vice versa.

In addition to offering a customizable polarity array, the rows orarrays of multiple magnets 48 of the first coupling member 30 and secondcoupling member 32 offer structural flexibility. Any number of magnetsmay be incorporated into an array to form a curve or other non-linear ornon-planar surface for attachment against a person's body or anothersurface that is not flat while still being able to hold relatively heavyitems. Ferromagnetic materials, such as the strong magnets used in theembodiments described in the present disclosure, are hard, brittlematerials with very little ductility or flexibility. As shown in FIG. 5,the multiple magnets 48 split into individual arrays 50, 52 utilize thelarge surface area of the entire magnetic array while allowingflexibility with the attachment member 16, such as the belt 38. The belt38 having the split, segmented, or arrayed magnets 48 of the secondcoupling member 32 benefits from the ability to bend, flex, or otherwiseform around a person's body. In addition to the removable member 14,other items capable of being attracted to the second coupling member 32may be secured to the attachment member, the belt incorporating magnets48, or other article incorporating the magnets 48 of the second couplingmember 32, such as a dog treat container or a legally concealed weapon.Similarly, the split, segmented, or arrayed magnets 48 of the removablemember 14 allow secure coupling to the attachment member 16, as well asto any shape, size, or type of exterior surface, such as the variedgeometries of vehicle body panels.

Referring now to FIG. 6, a magnetic belt assembly 110 is provided inaccordance with one or more embodiments of the present disclosure. Thebelt assembly 110 includes a first belt portion 112 having a firstcoupling member 114 and a second belt portion 116 having a secondcoupling member 118. Each of the first coupling member 114 and thesecond coupling member 118 includes a plurality of magnets 120. Each ofthe magnets 120 is moveable relative to each other such that each magnet120 of the plurality of magnets 120 is angularly positionable relativeto each other magnet 120 of the plurality of magnets 120 to form anon-planar surface 122, as illustrated in FIG. 9 and described infurther detail below. In one embodiment, the first belt portion 112defines a first end 124 of the magnetic belt assembly 110. In anembodiment, the second belt portion 116 defines a second end 126 of themagnetic belt assembly 110. The magnetic belt assembly 110 of anembodiment further includes a connecting portion 128 or third beltportion of the magnetic belt assembly 110 between the first end 124 andthe second end 126 of the magnetic belt assembly 110.

In one or more embodiments, multiple magnets 120 extend continuouslyfrom the first end 124 of the magnetic belt assembly 110 to the secondend 126 of the magnetic belt assembly 110. In an embodiment notillustrated, one or more central or end portions of the belt assembly110 do not include magnets 120.

The non-planar surface 122 is formed by each magnet 120 of the pluralityof magnets 120 being split from each other magnet 120 of the pluralityof magnets 120. Each individual magnet 120 of the plurality of magnets120 is rigid, brittle, non-deformable, and/or otherwise inflexible in anembodiment. In an additional embodiment, one or more of the plurality ofmagnets 120 is individually elastic, deformable, and/or otherwiseflexible.

Referring now to FIG. 7, the belt assembly 110 of an embodiment beingworn by a user 190 is illustrated. The belt assembly 110 of oneembodiment includes a fastening assembly 130 configured to fasten thefirst end 124 to the second end 126. In another embodiment, the beltassembly 110 does not include the fastening assembly 130. In anyembodiment of the belt assembly 110, one or more of the magnets 120 atthe first end 124 and one or more magnets 120 at the second end 126 willallow coupling of the first end 124 and the second end 126. Further, asillustrated in FIG. 7, an attached object 184, such as a pouch, tool, orany other article, includes one or a plurality of magnets 120 such thatthe attached object 184 is configured to be coupled to the belt assembly110. Attachment of the attached object 184 may occur at a predeterminedlocation or with a particular orientation, as explained in furtherdetail below with regard to FIG. 9. In a further embodiment, theattached object 184 may be incapable of being attached to the beltassembly 110, such as at one or more locations or all locations of thebelt assembly 110, by virtue of the arrangement of one or more magnets120.

Referring now to FIG. 8, the belt assembly 110 of one embodimentincludes a first layer 132 and a second layer 134. The first layer 132is coupled to the second layer 134 to embed one or more magnets 120,including magnets 120 of the first coupling member 114 and/or the secondcoupling member 118, therebetween. In an embodiment, an internal cavity136 is formed between the first layer 132 and the second layer 134. Theinternal cavity 136 is formed by the first layer 132 defining a firstplanar side 138 of the magnetic belt assembly 110 and being coupled tothe second layer 134 defining a second planar side 140 of the magneticbelt assembly 110.

Referring again to FIG. 6 with continuing reference to FIG. 8, in oneembodiment, the first layer 132 is coupled to the second layer 134between two adjacent magnets 120 such as by sewing, adhesive, integralformation, or one or more fasteners in non-limiting examples. In onenon-limiting example, the first layer 132 is sewn to the second layer134 at locations 192 between all adjacent magnets 120 in the beltassembly 110. Alternatively, the internal cavity 136 extendscontinuously from the first end 124 of the magnetic belt assembly 110 tothe second end 126 of the magnetic belt assembly 110 in an embodiment.In one embodiment, the first layer 132 and the second layer 134 are sewntogether continuously, such as at, near, or along a top edge 194 and abottom edge 196, from the first end 124 to the second end 126 to formthe internal cavity 136. In one embodiment, the first layer 132 is notcoupled to the second layer 134 between two adjacent magnets 120 suchthat one or more magnets 120 are capable of moving lengthwise throughthe internal cavity 136. In an embodiment not illustrated, the firstlayer 132 is coupled to the second layer 134 between two adjacentmagnets 120 in a first area of the belt assembly 110 while the firstlayer 132 is not coupled to the second layer 134 between two adjacentmagnets 120 in another area.

Referring now to FIG. 9, an embodiment similar to the embodimentdescribed above with regard to FIG. 5 is illustrated. A top crosssectional view is illustrated of one embodiment that includes a firstportion 180, such as the first end 124 or another portion of the beltassembly 110, being coupled to a second portion 182, such as the secondend 126 or another portion of the belt assembly 110, by the plurality ofmagnets 120. Alternatively, as illustrated in FIG. 7, the first portion180 or the second portion 182 is an attached object 184, such as apouch, tool, or any other article to name non-limiting examples, havingone or a plurality of magnets 120 for coupling to the belt assembly 110.Each magnet 120 of the plurality of magnets 120 is arranged in a variedpolarity array 150 such that two magnets 120 that are angularlypositionable to form the non-planar surface 122 are positioned in thearray 150 with reversed polarity relative to the other. In onenon-limiting example, a first magnet 144 in a first polarityconfiguration 154 is positioned in the first array 150 adjacent a secondmagnet 146 in a second polarity configuration 156 different from thefirst polarity configuration 154. In a second array 152, a third magnet148 in the second polarity configuration 158 is positioned adjacent to afourth magnet 170 in the first polarity configuration 160 such that thefirst and second magnets 144, 146 are properly attracted to the thirdand fourth magnets 148, 170.

The particular configuration of each magnet 120 may be varied so long aseach of the magnets 120 positioned in the first array 150 is attractedto each correspondingly positioned magnet 120 of the second array 152.As can be expected, there are many possible configurations of matedarrays as determined by the number of magnets 120 in each array.Accordingly, the number of configurations is 2^(n) where n is the numberof magnets in each array. In the embodiment shown in FIG. 9, there areeight configurations. However, any number of magnets may be used toincrease or decrease the number of potential configurations, and anyarray shape or design may be used to create the mated first array 150and second array 152. The variety of polarity configurations allows fora customization or organization opportunity as a particular object 184may properly couple at a predetermined location of the belt assembly 110due to the unique, matching configuration of the magnets of each.Further, the variety of polarity configurations allows for the beltassembly 110 to attach to itself and fasten at a predetermined locationto secure itself to a particular person or around an object. Further,the first coupling member 114 or the second coupling member 118 may notcontain magnets, or ferromagnetic materials. For example, if there areone or more magnets 120, in an array or otherwise, incorporated as thefirst coupling member 114, the second coupling member 118 need onlycomprise a ferrous or other material to which the magnet(s) 120 arecapable of attracted, and vice versa.

In addition to offering a customizable polarity array, the rows orarrays of multiple magnets 120 of the first coupling member 114 andsecond coupling member 118 offer structural flexibility. Any number ofmagnets may be incorporated into an array to form a curve or othernon-linear or non-planar surface for attachment against a person's bodyor another surface that is not flat while still being able to holdrelatively heavy items. Ferromagnetic materials, such as the strongmagnets used in the embodiments described in the present disclosure, arehard, brittle materials with very little ductility or flexibility. Asshown in FIG. 9, the multiple magnets 120 split into individual arrays150, 152 utilize the large surface area of the entire magnetic arraywhile allowing flexibility with the belt assembly 110. The belt assembly110 having the split, segmented, or arrayed magnets 120 of the secondcoupling member 118 benefits from the ability to bend, flex, orotherwise form around a person's body. In addition to the object 184,other items capable of being attracted to the belt assembly 110, oranother article coupled to the belt assembly 110 and incorporating themagnets 120, such as a dog treat container or a legally concealedweapon. Similarly, the split, segmented, or arrayed magnets 120 of thebelt assembly 110 allow secure coupling to any shape, size, or type ofsurface, such as the varied geometries of vehicle body panels.

While particular embodiments of the present disclosure have beenillustrated and described, it would be obvious to those skilled in theart that various other changes and modifications can be made withoutdeparting from the spirit and scope of the disclosure. It is thereforeintended to cover in the appended claims all such changes andmodifications that are within the scope of this disclosure.

What is claimed is:
 1. A magnetic belt assembly, comprising: a firstbelt portion having a first coupling member; and a second belt portionhaving a second coupling member, wherein each of the first couplingmember and the second coupling member comprises a plurality of magnetsthat is structurally flexible such that each magnet of the plurality ofmagnets is angularly positionable relative to each other magnet of theplurality of magnets to form a non-planar surface.
 2. The magnetic beltassembly of claim 1, wherein the first belt portion defines a first endof the magnetic belt assembly.
 3. The magnetic belt assembly of claim 2,wherein the second belt portion defines a second end of the magneticbelt assembly.
 4. The magnetic belt assembly of claim 2, wherein thesecond belt portion defines a connecting portion of the magnetic beltassembly between the first end and a second end of the magnetic beltassembly.
 5. The magnetic belt assembly of claim 1, wherein the firstbelt portion includes a first layer and a second layer, the first layerbeing coupled to the second layer to embed the first coupling membertherebetween.
 6. The magnetic belt assembly of claim 5, wherein thesecond belt portion includes the first layer and the second layer, thefirst layer being coupled to the second layer to embed the secondcoupling member therebetween.
 7. The magnetic belt assembly of claim 5,wherein the first layer is coupled to the second layer between twoadjacent magnets.
 8. The magnetic belt assembly of claim 5, furthercomprising an internal cavity between the first layer and the secondlayer, the internal cavity extending continuously from the first end ofthe magnetic belt assembly to the second end of the magnetic beltassembly.
 9. The magnetic belt assembly of claim 8, wherein the firstlayer and the second layer are sewn together continuously from the firstend to the second end to form the internal cavity.
 10. The magnetic beltassembly of claim 1, wherein the plurality of magnets extend from afirst end of the magnetic belt assembly to a second end of the magneticbelt assembly.
 11. The magnetic belt assembly of claim 1, wherein thenon-planar surface is formed by each magnet of the plurality of magnetsbeing split from each other magnet of the plurality of magnets.
 12. Themagnetic belt assembly of claim 11, wherein each magnet of the pluralityof magnets is arranged in a varied polarity array such that two magnetsthat are angularly positionable to form a non-planar surface arepositioned in the array with reversed polarity relative to the other.13. The magnetic belt assembly of claim 11, wherein each of theplurality of magnets is inflexible.
 14. A magnetic belt assembly,comprising; a first belt portion defining a first end of the magneticbelt assembly and having a first coupling member; a second belt portiondefining a second end of the magnetic belt assembly and having a secondcoupling member; and a third belt portion connecting the first end ofthe magnetic belt assembly to the second end of the magnetic beltassembly and having a third coupling member, wherein each of the firstcoupling member, the second coupling member, and the third couplingmember comprises a plurality of magnets that is structurally flexiblesuch that each magnet of the plurality of magnets is angularlypositionable relative to and split from each other magnet of theplurality of magnets to form a non-planar surface.
 15. The magnetic beltassembly of claim 14, further comprising an internal cavity extendingfrom the first end of the magnetic belt assembly to the second end ofthe magnetic belt assembly.
 16. The magnetic belt assembly of claim 15,wherein the plurality of magnets are disposed within the internal cavityand extend from the first end of the magnetic belt assembly to thesecond end of the magnetic belt assembly.
 17. The magnetic belt assemblyof claim 16, wherein the internal cavity is formed by a first layerdefining a first planar side of the magnetic belt assembly and beingcoupled to a second layer defining a second planar side of the magneticbelt assembly.
 18. The magnetic belt assembly of claim 16, wherein afirst layer and a second layer are sewn together continuously from thefirst end to the second end to form the internal cavity.
 19. Themagnetic belt assembly of claim 14, wherein each magnet of the pluralityof magnets is arranged in a varied polarity array such that two magnetsthat are angularly positionable to form the non-planar surface arepositioned in the array with reversed polarity relative to the other.20. The magnetic belt assembly of claim 14, wherein each magnet of theplurality of magnets is inflexible.